江汉盆地西南缘白垩系渔洋组砂岩储集层成岩作用和孔隙演化

江汉盆地西南缘白垩系渔洋组储集层成岩作用主要包括机械压实、早期碳酸盐和硫酸盐胶结、石英和长石的次生加大、长石和早期碳酸盐的溶蚀、晚期碳酸盐的沉淀,成岩阶段处于晚成岩A期。压实作用和胶结作用使原生孔隙损失殆尽,溶蚀作用形成的次生孔隙是油气的主要储集空间。纵向上发育两个次生孔隙带,第一次生孔隙带埋深2 800 m～3 100 m,其形成主要与有机质成熟过程释放有机酸对碳酸盐胶结物和长石等的溶解有密切关系,第二次生孔隙带埋深3 300 m～3 600 m,其形成可能是由于硫酸盐热化学氧化还原反应的作用。次生孔隙的发育受到温度和流体性质的控制,断裂是酸性水从烃源岩注入储集岩的重要通道,长期继承性的构造高部位成为了溶蚀作用和次生孔隙发育的有利位置。     

鄂尔多斯盆地塔巴庙地区上古生界砂岩储层"酸性+碱性"叠加溶蚀作用与储层质量主控因素

从岩石学薄片观察、埋藏史恢复、成岩流体包裹体检测、地层水化学特征和砂岩、粘土矿物成岩作用及储层性能评价等入手,对鄂尔多斯盆地塔巴庙地区上古生界下石盒子-山西组砂岩储层储集性能主控因素进行了初步探讨.研究成果认为:(1)工区下石盒子-山西组砂岩储层在早白垩世达到最大埋深(约4500m),强压实和高含量岩屑变形以及杂基充填粒间,使得砂岩原生粒间孔隙几乎完全丧失,储集空间主要为次生溶蚀孔隙,原生孔隙不发育;(2)碳酸盐胶结物和少量长石及岩屑在中等埋藏深度发生酸性溶蚀,而石英骨架颗粒和泥质、微晶石英杂基在深埋藏阶段发生碱性溶蚀,从而形成“酸性 碱性”叠加溶蚀次生孔隙带,成为控制工区目的层储层质量的主控因素;(3)粘土矿物演化剖面、地层水化学剖面和储层物性与储层岩屑、方解石、自生硅质和填隙物含量关系对比剖面,揭示大约在2670m附近存在一个重要的界面,在此界面之上为酸性溶蚀带,在此界面之下为先期酸性、后期叠加碱性溶蚀的深部次生孔隙带,其中在2670～2740m深度段为高孔高渗带,天然气沿此深度带优先充注.因此,这个带也是一个天然气高产带,在今后的勘探应给予高度重视.     

惠民凹陷古近系碎屑岩次生孔隙纵向分布规律

为了在油气勘探的过程中更加准确地预测有效储层的分布, 根据铸体薄片、扫描电镜、碳酸盐含量、镜质体反射率、粘土矿物以及储层物性等数据, 研究了惠民凹陷古近系砂岩次生孔隙的纵向分布规律.在小于1400m的深度, 砂岩的孔隙主要为压实和胶结之后的原生粒间孔隙; 在埋深超过1400m以后开始出现少量次生孔隙, 在1400~1500m深度范围形成原生孔隙与次生孔隙并存的混合孔隙带; 超过1500m, 大量的次生孔隙出现在1500~2300m和2700~4000m的2个深度段.所收集的砂岩孔隙度和渗透率数据在纵向上的变化关系也间接证实了这一点.次生孔隙主要为长石溶蚀成因, 碳酸盐胶结物溶蚀是次要的.在次生孔隙发育带内, 惠民凹陷烃源岩演化产生大量有机酸和泥岩中的粘土矿物迅速脱水是产生溶蚀作用形成次生孔隙的直接原因.      

济阳坳陷古近系成岩作用及其对储层质量的影响?

大量的储层分析化验资料研究表明，济阳坳陷古近系砂岩储层经历了压实、胶结等多种成岩作用。压实作用以机械压实为主，压溶作用较少。胶结作用主要有十分普遍的石英次生加大胶结、碳酸盐胶结、粘土矿物胶结。碳酸盐胶结物有早、晚两期，早期泥晶方解石主要分布在浅层，连晶方解石充填的深度分布范围大，中深部最为发育。溶蚀作用主要有碳酸盐胶结物、长石颗粒和少量岩屑溶蚀。储层孔隙经历了由原生到次生的演化过程，在成岩演化过程中，长石的溶蚀作用、碳酸盐矿物的沉淀与溶解作用是影响孔隙大小的关键因素，早期方解石的胶结有利于后期次生孔隙的发育。不同凹陷次生孔隙发育的深度不同。在济阳坳陷西部的惠民凹陷次生孔隙主要发育于1500-2400m深度，向东至东营凹陷则主要发育于1650-2450m，再向东到沾化凹陷为2300-3500m，车镇凹陷为2200-2700m。从西向东、由南向北次生孔隙的发育深度逐步增大是受盆地沉积沉降中心的迁移规律控制的。     

珠江口盆地白云凹陷深层储层特征与有效储层控制因素

珠江口盆地白云凹陷珠海组和恩平组是该区深层油气勘探的主要层系,查明深层储层基本特征和有效储层控制因素对于白云凹陷深层油气勘探具有重要意义. 基于岩石学和矿物学、成岩作用、孔隙特征及沉积相分析,明确了白云凹陷深层储层基本特征. 白云凹陷深层以低孔低渗和致密储层为主;压实作用是造成深层储层变差的主要原因,碳酸盐胶结和石英次生加大是主要的自生矿物;孔隙类型以粒间溶孔和粒内溶孔为主;有效储层以低孔低渗及以上储层为主,孔隙度总体保持在10%左右,渗透率变化范围大. 中粗粒沉积相带、溶蚀作用和超压是深层有效储层的主要控制因素. 中粗粒砂岩具有较好的原生孔和次生孔发育条件,渗透率较高,胶结减孔作用弱,溶蚀增孔作用强;溶蚀作用是深层关键的建设性成岩作用,溶蚀孔隙是深层主要的孔隙类型;超压传导作用有利于酸性流体活动和溶蚀物质的迁移,对形成溶蚀孔隙具有积极意义;分流河道和水下分流河道砂体是中粗粒砂岩的主要载体,应作为深层油气勘探的优选对象.      

松辽盆地北部深层砂岩成岩作用与孔隙演化

松辽盆地北部深层砂岩成岩作用强,原生孔隙保存差。深层砂岩只有出现大量的次生孔隙,才能具有较好的储集性能。本文通过偏光显微镜、扫描电镜和显微热台等分析方法,研究了松辽盆地深层砂岩岩石类型,成岩作用特征和各成岩阶段砂岩孔隙的演化,表明胶结作用是影响深层砂岩储层物性变差的主要原因,浊沸石胶结物的溶解是深部砂岩储集性能得以改善的主要原因。     

基于星点状方解石胶结与溶解的识别查明砂岩粒间孔隙类型——以雅布赖盆地新河组砂岩为例

目前含油气砂岩中粒间孔隙是原生孔隙还是次生孔隙的认识仍不一致,而对星点状方解石胶结与溶解的识别能够有效地查明粒间孔隙的类型。文章通过铸体薄片细致地观察雅布赖盆地新河组砂岩中的微观现象,以成岩环境演化和成岩序列分析为主线,重视方解石胶结物的赋存状态与物质来源和溶蚀流体来源的配置关系,精细解剖微观现象,从而弄清楚星点状方解石的成因,进而查明砂岩的粒间孔隙类型和储集空间类型。结果表明,粒间孔隙中的星点状方解石是成岩早期浸染状方解石胶结物的溶蚀残余,溶蚀流体为成岩中期的有机酸流体,溶蚀类型为一致性溶解,形成的粒间孔隙为次生孔隙。鉴于此,雅布赖盆地新河组砂岩的储集空间由次生粒间孔隙和次生粒内孔隙（长石、岩屑、方解石胶结物的溶蚀孔隙）组成。      

准噶尔盆地西北缘克-百地区侏罗系成岩作用及其对储层质量的影响

准噶尔盆地西北缘克拉玛依—百口泉地区侏罗系砂岩、砂砾岩储层经历了压实、胶结、溶蚀等多种成岩作用,其中压实和溶蚀作用是控制储层物性的主要成岩作用,其次为胶结作用。压实作用以机械压实为主,是孔隙减少的主要原因。胶结作用主要为碳酸盐胶结,少量黄铁矿胶结,偶见方沸石胶结和硅质胶结。溶蚀作用导致碳酸盐胶结物、长石颗粒和少量岩屑溶解流失。储层孔隙经历了由原生到次生的演化过程。在成岩演化过程中,长石的溶蚀作用、碳酸盐矿物的沉淀与溶解作用是影响储层孔隙发育的关键因素,早期方解石的胶结有利于后期次生孔隙的形成。在克-乌断裂带上、下盘地层中,断裂带上盘埋深浅,一般小于1200m,原生孔隙非常发育;断裂带下盘埋深较深,压实作用强,原生孔隙所占比例明显减少,次生溶蚀孔隙相对发育。次生孔隙的形成受流体及断裂控制。     

莺歌海盆地LD区块地层超压对储层成岩作用的影响及其地质意义

莺歌海盆地异常地层压力的分布状况、异常地层压力条件下的流-岩相互作用以及其对储层成岩演化影响方面的研究尚未展开, 综合应用岩石薄片鉴定、扫描电镜分析、稳定同位素分析、流体包裹体均一温度测试等技术, 系统分析了莺歌海盆地LD区现今压力分布特征、超压环境下储层成岩作用特征及超压流体活动对储层成岩演化的影响.结果表明: (1)地层超压驱动深层热流体向上释放, 富含碳酸盐类离子成分的热流体运移到超压顶界面附近时由于温压条件变化而重新沉淀, 形成高含量的碳酸盐胶结物致密层; (2)地层超压通过抑制粘土矿物的转化来减少碳酸盐胶结物的生成和石英次生加大, 使原生孔隙得以有效保存; (3)LD区块储层普遍富含CO₂, 在超压环境下CO₂在流体中溶解度增大, 会大量生成H+; 另外一方面, 超压增加了LD区块有机酸的释放空间和时间, 促进溶蚀作用的产生.由此可知, 造成研究区中深部超压储层具有较高的孔隙度的主要因素为超压抑制了胶结物的生成, 其次为超压降低了机械压实作用及促进了次生孔隙的发育.      

博兴洼陷沙四上亚段滩坝砂岩次生孔隙形成机制

根据砂岩铸体薄片、扫描电镜、地层压力分析,研究了博兴洼陷沙四上亚段滩坝砂岩次生孔隙的形成机制.研究表明博兴洼陷地层中的上升流为滩坝砂岩次生孔隙的形成创造了条件,硅酸盐和碳酸盐矿物在CO2和有机酸作用下的溶蚀是次生孔隙形成的主要因素,黏土矿物的转化也为次生孔隙的发育做出了贡献.在构造高部位碳酸盐胶结程度较低或断层较发育的区域次生孔隙较发育,在构造高部位侧翼的厚层滩坝砂岩次生孔隙也较发育.依据次生孔隙的结构特征、胶结物的性质和产状、碎屑颗粒的性质将博兴洼陷滩坝砂岩划分为4种成岩相:其中不稳定碎屑溶蚀成岩相控制的区域次生孔隙最为发育,可成为较好的油气聚集区;碳酸盐胶结和压实-溶蚀成岩相控制的地区次生孔隙发育次之,但也可以成为油气聚集区;压实成岩相基本不具储集性能.     

Carbonate cementation-dissolution in deep-seated sandstones near the overpressure top in central Junggar Basin,Xinjiang, NW China

Fluid/rock interaction occurs frequently in the sandstones near the overpressure top in central Junggar Basin, and carbonate cementation-dissolution is related closely to the formation of secondary pores in the reservoir sandstones. From petrological, hydrochemical and fluid-inclusion studies of the deep-seated sandstones near the overpressure top in central Junggar Basin and the carbon and oxygen isotopic characteristics of carbonate cements in those sandstones, the following conclusions can be drawn: (1) Carbonates are the major cements. Two-stage cemen-tation was commonly developed, with late-stage ferroan carbonate cementation being dominant; several secondary porosity zones were developed vertically in the sandstones near the overpressure top, and there is a mutually com-pensatory relationship between the carbonate contents and the mean porosity; (2) the alkalescent formation-water chemical environments are in favor of carbonate precipitation; (3) there were two phases of thermal fluid activity which are related to the late-stage carbonate cementation-dissolution; (4) with the overpressure top as the boundary, carbonate cements in the sandstones have slightly negative δ13C and δ180 values, showing such a variation trend that the δ13C and δ18O values near the coal-bearing Jurassic strata are lighter, those in the overpressure top are heavier, and those at the upper part of the overpressure top are lighter, which is considered to be the result of kinetic isotope fractionation driven by episodically overpressured fluid flow; (5) carbonate cementation is closely associated with the decarboxylation of organic acids, and secondary porosity zones resultant from dissolution by organic acids and CO2 derived from Jurassic coal-beating strata, are the most important reservoir space of hydrocarbon, Studies of the mechanisms of carbonate cementation-dissolution and formation of secondary pores in the deep-seated sandstones near the overpressure top are of great significance both in theory and in practice in further investigating the rules of overpressured fluid flow (especially oil/gas migration) and predicting the reservoir space of hydrocarbon.     

准噶尔盆地腹部永进地区砂岩储层中碳酸盐胶结物特征及其成因意义

准噶尔盆地腹部永进地区不整合面附近砂岩储层中次生孔隙和碳酸盐胶结物相对发育.通过薄片观察、阴极发光、扫描电镜/能谱分析,认为碳酸盐胶结物是研究区砂岩最主要的胶结物成分,其主要类型为(铁)方解石和铁白云石,垂向上含量随深度增加而增加,多集中分布在白垩系和侏罗系之间的不整合面之下约100 m的范围之内.碳、氧同位素分析以及泥岩中各元素测试结果表明,大气淡水通过永进地区白垩系和侏罗系之间存在的角度不整合对其下伏地层物性作用不明显,晚期含铁碳酸盐胶结物和孔隙发育主要与有机酸关系密切.在有机酸作用下,早期发育的碳酸盐胶结物、长石碎屑颗粒以及粘土矿物为晚期碳酸盐胶结物的发育提供了物质基础,而且溶解的物质在酸性流体作用下运移至不整合面附近重新沉淀,造成高孔隙度和高含量碳酸盐胶结物在深度上具有重叠的特征.由于含铁碳酸盐胶结物形成时代晚而且储层未受到其他建设性成岩作用的明显改造,晚期碳酸盐胶结物含量和面孔率呈互相补偿的关系, 表明了晚期碳酸盐胶结物对储层物性的破坏作用.     

早期碳酸盐胶结作用对砂岩孔隙演化的影响——以塔里木盆地满加尔凹陷志留系砂岩为例

塔里木盆地满加尔凹陷志留系砂岩为无障壁的潮坪、滨岸及辫状河三角洲沉积的岩屑砂岩和岩屑质石英砂岩,对满北和满东、满南地区志留系砂岩成岩作用序次尤其是碳酸盐胶结的时间、方式和特征、物性的对比研究认为:砂岩中碳酸盐胶结的时间早晚对砂岩孔隙演化具有重要影响,满北地区志留系砂岩发育有大量早期泥晶碳酸盐胶结,显微镜下研究表明这种胶结作用发生在岩石受到充分压实之前,呈基底式胶结,岩石颗粒呈点接触或漂浮状分布于早期碳酸盐胶结物之中,这种胶结作用抑制了岩石后期的压实作用。尽管目前其埋藏达5 000～6 500 m,但其经历的压实作用并不强烈,粒间发育大量早期的碳酸盐胶结物,后来这些胶结物被溶蚀,形成了大量次生孔隙。而在满东和满南地区的志留系砂岩,碳酸盐胶结发生在岩石经过充分压实之后,晚期的碳酸盐胶结物仅分布于岩石经充分压实后的粒间孔隙中,含量较前者低,后期可供溶蚀的碳酸盐比前者少,因而溶蚀形成的次生孔隙有限。因此,尽管满东满南地区志留系埋藏比满北浅（3 700～5 000 m）,碳酸盐胶结物含量也低,也发育晚期碳酸盐胶结物的溶蚀,但岩石的压实作用比满北强,物性比满北低差。这主要与碳酸盐胶结的早晚有关,早期碳酸盐胶结对孔隙演化具有明显控制作用,有利于岩石孔隙的保存,为后来的溶蚀形成次生孔隙提供了条件。     

酒东坳陷下白垩统砂岩中碳酸盐胶结物特征与储层物性

碳酸盐胶结物是酒东坳陷下白垩统砂岩内一种重要的自生矿物,其对深部储层储层质量有着重要影响。本文通过薄片观察、扫描电镜、能谱分析及碳氧同位素分析,认为碳酸盐胶结物主要为铁方解石、白云石和铁白云石,并且以后者为主,其分布具有不均一性且分带性明显。碳酸盐胶结物均为成岩作用后期产生,形成该矿物所需的物质主要来源于泥岩的黏土矿物...     

惠州凹陷东部珠海组储层碱性成岩作用及孔隙演化

根据铸体薄片、扫描电镜、粒度分析、X衍射等资料,对惠州凹陷东部珠海组储层的岩石学特征、成岩作用和孔隙演化过程进行分析研究。研究认为,惠州凹陷东部珠海组储层的岩石类型以岩屑砂岩、长石质岩屑砂岩、岩屑质石英砂岩和岩屑质长石砂岩为主,结构成熟度与成分成熟度较低。砂岩埋藏过程中经历了明显的碱性成岩作用:石英的溶蚀与交代、碳酸盐矿物胶结、伊利石和绿泥石的沉淀以及钠长石化等。碱性成岩作用对孔隙的影响包括:石英溶蚀形成次生溶孔、碳酸盐胶结物沉淀损失粒间孔隙、黏土矿物沉淀形成晶间微孔。研究区珠海组主要发育粒内溶孔和粒间溶孔,原生孔隙较少。储层现今处于中成岩阶段A期,早期经历了强烈的压实作用,使其孔隙度由原始孔隙度32.1%降低至8.8%。早成岩阶段为碱性成岩环境,石英溶蚀增孔约0.5%;碳酸盐、硫酸盐、伊利石等胶结物沉淀减孔约2.3%。中成岩阶段A期为酸性成岩环境,硅质、高岭石等胶结物沉淀减孔约1.2%;长石、岩屑等溶蚀增孔约4.3%。最终,储层演化至现今孔隙度10.1%。     

Diagenesis in the Middle Jurassic Khatatba Formation sandstones in the Shoushan Basin,northern Western Desert,Egypt

The Middle Jurassic Khatatba Formation acts as a hydrocarbon reservoir in the subsurface in the Western Desert, Egypt. This study, which is based on core samples from two exploration boreholes, describes the lithological and diagenetic characteristics of the Khatatba Formation sandstones. The sandstones are fine‐ to coarse‐grained, moderately to well‐sorted quartz arenites, deposited in fluvial channels and in a shallow‐marine setting. Diagenetic components include mechanical and chemical compaction, cementation (calcite, clay minerals, quartz overgrowths, and a minor amount of pyrite), and dissolution of calcite cements and feldspar grains. The widespread occurrence of an early calcite cement suggests that the Khatatba sandstones lost a significant amount of primary porosity at an early stage of its diagenetic history. In addition to calcite, several different cements including kaolinite and syntaxial quartz overgrowth occur as pore‐filling and pore‐lining cements. Kaolinite (largely vermicular) fills pore spaces and causes reduction in the permeability of the reservoir. Based on framework grain–cement relationships, precipitation of the early calcite cement was either accompanied by or followed the development of part of the pore‐lining and pore‐filling cements. Secondary porosity development occurred due to partial to complete dissolution of early calcite cements and feldspar. Late kaolinite clay cement occurs due to dissolved feldspar and has an impact on the reservoir quality of the Khatatba sandstones. Open hydraulic fractures also generated significant secondary porosity in sandstone reservoirs, where both fractures and dissolution took place in multiple phases during late diagenetic stages. The diagenesis and sedimentary facies help control the reservoir quality of the Khatatba sandstones. Fluvial channel sandstones have the highest porosities and permeabilities, in part because of calcite cementation, which inhibited authigenic clays or was later dissolved, creating intergranular secondary porosity. Fluvial crevasse‐splay and marine sandstones have the lowest reservoir quality because of an abundance of depositional kaolinite matrix and pervasive, shallow‐burial calcite and quartz overgrowth cements, respectively. Copyright © 2013 John Wiley & Sons, Ltd.     

成岩作用对河流-三角洲相砂岩储层物性演化的影响--以延长油区上三叠统延长组长2砂岩为例

延长油区上三叠统长 2地层河流相-三角洲相砂岩储层的物性明显受埋藏-成岩作用事件的影响。埋藏压实作用是导致砂岩孔隙丧失的主要原因,造成的平均孔隙度丧失为 17.8%。其中黑云母的早期成岩蚀变是造成原生孔隙丧失的一个重要原因。胶结作用造成的平均孔隙度丧失为 7.1%。其中碳酸盐胶结物和次生石英加大是造成砂岩物性降低的主要胶结物。碎屑颗粒周围绿泥石薄膜的存在阻止了一部分石英次生加大及碳酸盐胶结物的沉淀,使一部分原生粒间孔隙得以保存。晚期成岩阶段有机质分解形成的酸性流体及表生成岩作用阶段的大气降水是形成次生孔隙的主要原因,从而使长 2砂岩的物性得到改善     

陕北青化砭油田长2砂岩储层物性的控制因素

青化砭油田上三叠统长2辫状河砂岩储集层物性主要受沉积相及成岩作用的控制。沉积相通过控制储集岩的颗粒粒度及粘土矿物含量来控制储集物性,河道中心砂岩的物性好于河道侧翼砂岩,河道间沉积的储集物性最差。压实作用是造成砂岩原生孔隙丧失的主要原因,碳酸盐矿物和石英的次生加大胶结是降低储层物性的主要胶结作用,经溶解作用改造的辫状河河道砂体成为储集性能良好的油气储集体,是今后研究区长2油层组的主攻目标。     

Halite cementation and carbonate diagenesis of intra-salt reservoirs from the Late Neoproterozoic to Early Cambrian Ara Group (South Oman Salt Basin)

Late Neoproterozoic to Early Cambrian carbonates of the Ara Group form important intra‐salt ‘stringer’ reservoirs in the South Oman Salt Basin. Differential loading of thick continental clastics above the six carbonate to evaporite cycles of the Ara Group led to the formation of salt diapirs, encasing a predominantly self‐charging hydrocarbon system within partly highly overpressured carbonate bodies (‘stringers’). These carbonates underwent a complex diagenetic evolution, with one stage of halite cementation in a shallow (early) and another in a deep (late) burial environment. Early and late halite cements are defined by their microstructural relationship with solid bitumen. The early phase of halite cementation is post‐dated by solid reservoir bitumen. This phase is most pervasive towards the top of carbonate stringers, where it plugs nearly all available porosity in facies with initially favourable poroperm characteristics. Bromine geochemistry revealed significantly higher bromine contents (up to 280 p.p.m.) in the early halite compared with the late halite (173 p.p.m.). The distribution patterns and the (high) bromine contents of early halite are consistent with precipitation caused by seepage reflux of highly saturated brines during deposition of the overlying rock salt interval. Later in burial history, relatively small quantities of early halite were dissolved locally and re‐precipitated as indicated by inclusions of streaky solid bitumen within the late halite cements. Late halite cement also seals fractures which show evidence for repeated reopening. Initially, these fractures formed during a period of hydrothermal activity and were later reopened by a crack‐seal mechanism caused by high fluid overpressures. Porosity plugging by early halite cements affects the poroperm characteristics of the Ara carbonates much more than the volumetrically less important late halite cement. The formation mechanisms and distribution patterns of halite cementation processes in the South Oman Salt Basin can be generalized to other petroliferous evaporite basins.